【 摘 要 】

Background

Previous research programmes have described muscle biochemical traits and gene expression levels associated with beef tenderness. One of our results concerning the DNAJA1 gene (an Hsp40) was patented. This study aims to confirm the relationships previously identified between two gene families (heat shock proteins and energy metabolism) and beef quality.

Results

We developed an Agilent chip with specific probes for bovine muscular genes. More than 3000 genes involved in muscle biology or meat quality were selected from genetic, proteomic or transcriptomic studies, or from scientific publications. As far as possible, several probes were used for each gene (e.g. 17 probes for DNAJA1). RNA from Longissimus thoracis muscle samples was hybridised on the chips. Muscles samples were from four groups of Charolais cattle: two groups of young bulls and two groups of steers slaughtered in two different years. Principal component analysis, simple correlation of gene expression levels with tenderness scores, and then multiple regression analysis provided the means to detect the genes within two families (heat shock proteins and energy metabolism) which were the most associated with beef tenderness. For the 25 Charolais young bulls slaughtered in year 1, expression levels of DNAJA1 and other genes of the HSP family were related to the initial or overall beef tenderness. Similarly, expression levels of genes involved in fat or energy metabolism were related with the initial or overall beef tenderness but in the year 1 and year 2 groups of young bulls only. Generally, the genes individually correlated with tenderness are not consistent across genders and years indicating the strong influence of rearing conditions on muscle characteristics related to beef quality. However, a group of HSP genes, which explained about 40% of the variability in tenderness in the group of 25 young bulls slaughtered in year 1 (considered as the reference group), was validated in the groups of 30 Charolais young bulls slaughtered in year 2, and in the 21 Charolais steers slaughtered in year 1, but not in the group of 19 steers slaughtered in year 2 which differ from the reference group by two factors (gender and year). When the first three groups of animals were analysed together, this subset of genes explained a 4-fold higher proportion of the variability in tenderness than muscle biochemical traits.

Conclusion

This study underlined the relevance of the GENOTEND chip to identify markers of beef quality, mainly by confirming previous results and by detecting other genes of the heat shock family as potential markers of beef quality. However, it was not always possible to extrapolate the relevance of these markers to all animal groups which differ by several factors (such as gender or environmental conditions of production) from the initial population of reference in which these markers were identified.

【 授权许可】

   
2012 Hocquette et al.; licensee BioMed Central Ltd.

【 预 览 】

附件列表

Files	Size	Format	View
20150208114838558.pdf	252KB	PDF	download

【 参考文献 】

• [1]Bernard C, Cassar-Malek I, Renand G, Hocquette JF: Changes in muscle gene expression related to metabolism according to growth potential in young bulls. Meat Sci 2009, 82:205-212.
• [2]Sudre K, Cassar-Malek I, Listrat A, Ueda Y, Leroux C, Jurie C, Auffray C, Renand G, Martin P, Hocquette JF: Biochemical and Transcriptomic analyses of two bovine skeletal muscles in Charolais bulls divergently selected for muscle growth. Meat Sci 2005, 70:267-277.
• [3]Pareek CS, Smoczynski R, Pierzchala M, Czarnik U, Tretyn A: From genotype to phenotype in bovine functional genomics. Brief funct genomics 2011, 10:165-171.
• [4]Hughes LM, Bao J, Hu ZL, Honavar V, Reecy JM: Animal trait ontology: The importance and usefulness of a unified trait vocabulary for animal species. J Anim Sci 2008, 86:1485-1491.
• [5]Eggen A, Hocquette JF: Genomic approaches to economic trait loci and tissue expression profiling: application to muscle biochemistry and beef quality. Meat Sci 2004, 66:1-9.
• [6]Renand G, Picard B, Touraille C, Berge P, Lepetit J: Relationships between muscle characteristics and meat quality traits of young Charolais bulls. Meat Sci 2001, 59:49-60.
• [7]Cassar-Malek I, Picard B, Bernard C, Hocquette JF: Application of gene expression studies in livestock production systems: a European perspective. Aust J Exp Agr 2008, 48:701-710.
• [8]Mullen AM, Stapleton PC, Corcoran D, Hamill RM, White A: Understanding meat quality through the application of genomic and proteomic approaches. Meat Sci 2006, 74:3-16.
• [9]Hocquette JF, Lehnert S, Barendse W, Cassar-Malek I, Picard B: Recent advances in cattle functional genomics and their application to beef quality. Animal 2007, 1:159-173.
• [10]Hocquette JF, Cassar-Malek I, Bernard C, Picard B: Functional genomics and new markers for beef production. Anim Sci Pap Rep 2009, 27:273-280.
• [11]Bernard C, Cassar-Malek I, Hocquette JF: Genomic marker for meat tenderness. Patent 2006. 06 300943.5. 12 September 2006, WO/2005/052133
• [12]Bernard C, Cassar-Malek I, Le Cunff M, Dubroeucq H, Renand G, Hocquette JF: New indicators of beef sensory quality revealed by expression of specific genes. J Agr Food Chem 2007, 55:5229-5237.
• [13]Williams JL, Dunner S, Valentini A, Mazza R, Amarger V, Checa ML, Crisà A, Razzaq N, Delourme D, Grandjean F, Marchitelli C, García D, Pérez Gomez R, Negrini R, Ajmone Marsan P, Levéziel H: Discovery, characterization and validation of single nucleotide polymorphisms within 206 bovine genes that may be considered as candidate genes for beef production and quality. Anim Genet 2009, 40:486-491.
• [14]Bouley J, Meunier B, Chambon C, De Smet S, Hocquette JF, Picard B: Proteomic analysis of bovine skeletal muscle hypertrophy. Proteomics 2005, 5:490-500.
• [15]Picard B, Berri C, Lefaucheur L, Molette C, Sayd T, Terlouw C: Skeletal muscle proteomics in livestock production. Brief funct genomics 2010, 9:259-278.
• [16]Cassar-Malek I, Ueda Y, Bernard C, Jurie C, Sudre K, Listrat A, Barnola I, Gentès G, Leroux C, Renand G, Martin P, Hocquette JF: Molecular and biochemical muscle characteristics of Charolais bulls divergently selected for muscle growth. In Indicators of milk and beef quality. Edited by Hocquette JF, Gigli S. EAAP Publication 112, Wageningen Academic Publishers, Wageningen, The Netherlands; 2005:371-377.
• [17]Cassar-Malek I, Jurie C, Bernard C, Barnola I, Micol D, Hocquette JF: Pasture-feeding of charolais steers influences skeletal muscle metabolism and gene expression. J Physiol Pharmacol 2009, 60(Suppl 2):83-90.
• [18]Sudre K, Leroux C, Piétu G, Cassar-Malek I, Petit E, Listrat A, Auffray C, Picard B, Martin P, Hocquette JF: Transcriptome analysis of two bovine muscles during ontogenesis. J Biochem 2003, 133:745-756.
• [19]Chaze T, Bouley J, Chambon C, Barboiron C, Picard B: Mapping of alkaline proteins in bovine skeletal muscle. Proteomics 2006, 6:2571-2575.
• [20]Chaze T, Meunier B, Chambon C, Jurie C, Picard B: In vivo proteome dynamics during early bovine myogenesis. Proteomics 2008, 8:4236-4248.
• [21]Chaze T, Meunier B, Chambon C, Jurie C, Picard B: Proteome dynamics during contractile and metabolic differentiation of bovine foetal muscle. Animal 2009, 3:980-1000.
• [22]Guillemin N, Jurie C, Cassar-Malek I, Hocquette JF, Renand G, Picard B: Variations in the abundance of 24 proteins biomarkers of beef tenderness according to muscle and animal type. Animal 2011, 6:867-874.
• [23]Morzel M, Terlouw C, Chambon C, Micol D, Picard B: Muscle proteome and meat eating qualities of Longissimus thoracis of “Blonde d’Aquitaine” young bulls: A central role of HSP27 isoforms. Meat Sci 2008, 78:297-304.
• [24]Allais S, Journaux L, Levéziel H, Payet-Duprat N, Raynaud P, Hocquette JF, Lepetit J, Rousset S, Denoyelle C, Bernard-Capel C, Renand G: Effects of polymorphisms in the calpastatin and μ-calpain genes on meat tenderness in three French beef breeds. J Anim Sci 2011, 89:1-11.
• [25]Hocquette JF, Gondret F, Baéza E, Médale F, Jurie C, Pethick DW: Intramuscular fat content in meat-producing animals: development, genetic and nutritional control, identification of putative markers. Animal 2010, 4:303-319.
• [26]Jurie C, Cassar-Malek I, Bonnet M, Leroux C, Bauchart D, Boulesteix P, Pethick DW, Hocquette JF: Adipocyte fatty acid-binding protein and mitochondrial enzyme activities in muscles as relevant indicators of marbling in cattle. J Anim Sci 2007, 85:2660-2669.
• [27]Lehnert SA, Byrne KA, Reverter A, Nattrass G, Greenwood PL, Wang YH, Hudson NJ, Harper GS: Gene expression profiling of bovine skeletal muscle in response to and during recovery from chronic and severe undernutrition. J Anim Sci 2006, 84:3239-3250.
• [28]Lehnert SA, Reverter A, Byrne KA, Wang Y, Nattrass GS, Hudson NJ, Greenwood PL: Gene expression studies of developing bovine longissimus muscle from two different beef cattle breeds. BMC Dev Biol 2007, 7:95. BioMed Central Full Text
• [29]Wang YH, Byrne KA, Reverter A, Harper GS, Taniguchi M, McWilliam SM, Mannen H, Oyama K, Lehnert SA: Transcriptional profiling of skeletal muscle tissue from two breeds of cattle. Mamm Genome 2005, 16:201-210.
• [30]Wang YH, Reverter A, Mannen H, Taniguchi M, Harper GS, Oyama K, Byrne KA, Oka A, Tsuji S, Lehnert SA: Transcriptional profiling of muscle tissue in growing Japanese Black Cattle to identify genes involved with the development of intramuscular fat. Aust J Exp Agr 2005, 45:809-820.
• [31]Wang YH, Bower NI, Reverter A, Tan SH, De Jager N, Wang R, McWilliam SM, Cafe LM, Greenwood PL, Lehnert SA: Gene expression patterns during intramuscular fat development in cattle. J Anim Sci 2009, 87:119-130.
• [32]Lin CS, Hsu CW: Differentially transcribed genes in skeletal muscle of Duroc and Taoyuan pigs. J Anim Sci 2005, 83:2075-2086.
• [33]Jia XH, Ekman M, Grove H, Faergestad EM, Aass L, Hildrum KI, Hollung K: Proteome changes in bovine longissimus thoracis muscle during the early post-mortem storage period. J Proteome Res 2007, 6:2720-2731.
• [34]Jia XH, Hildrum KI, Westad F, Kummen E, Aass L, Hollung K: Changes in enzymes associated with energy metabolism during the early post mortem period in Longissimus thoracis bovine muscle analyzed by proteomics. J Proteome Res 2006, 5:1763-1769.
• [35]Pannier L, Sweeney T, Hamill RM, Ipek F, Stapleton PC, Mullen AM: Lack of an association between single nucleotide polymorphisms in the bovine leptin gene and intramuscular fat in Bos taurus cattle. Meat Sci 2009, 81:731-737.
• [36]Pannier L, Mullen AM, Hamill RM, Stapleton PC, Sweeney T: Association analysis of single nucleotide polymorphisms in DGAT1, TG and FABP4 genes and intramuscular fat in crossbred Bos taurus cattle. Meat Sci 2010, 85:515-518.
• [37]Potts JK, Echternkamp SE, Smith TPL, Reecy JM: Characterization of gene expression in double-muscled and normal-muscled bovine embryos. Anim Gen 2003, 34:438-444.
• [38]Guillemin N, Jurie C, Renand G, Hocquette JF, Micol D, Lepetit J, Levéziel H, Picard B: Different phenotypic and proteomic markers explain variability of beef tenderness across muscles. Int J Biol 2012, 4:26-38.
• [39]Dikeman ME, Reddy GB, Arthaud VH, Tuma HJ, Koch RM, Mandigo RW, Axe JB: Longissimus muscle quality, palatability and connective tissue histological characteristics of bulls and steers fed different energy levels and slaughtered at four ages. J Anim Sci 1986, 63:92-101.
• [40]Chang HJ, Xu XL, Li CB, Huang M, Liu DY, Zhou GH: A comparison of heat-induced changes of intramuscular connective tissue and collagen of beef semitendinosus muscle during water bath and microwave heating. J Food Process Eng 2010, 34:2233-2250.
• [41]Ouali A, Herrera-Mendez CH, Coulis G, Becila S, Boudjellal A, Aubry L, Sentandreu M: Revisiting the conversion of muscle into meat and the underlying mechanisms. Meat Sci 2006, 74:44-58.
• [42]Kemp CM, Sensky PL, Bardsley RG, Buttery PJ, Parr T: Tenderness – An enzymatic view. Meat Sci 2010, 84:248-256.
• [43]Park KM, Pramod AB, Kim JH, Choe HS, Hwang IH: Molecular and biological factors affecting skeletal muscle cells after slaughtering and their impact on meat quality: a mini-review. J Muscle Foods 2010, 21:280-307.
• [44]Kim NK, Cho S, Lee SH, Park HR, Lee CS, Cho YM, Choy YH, Yoon D, Im SK, Park EW: Proteins in longissimus muscle of Korean native cattle and their relationship to meat quality. Meat Sci 2008, 80:1068-1073.
• [45]Picard B, Chaze T, Meunier B, Renand G, Journaux L, Capel C, Hocquette JF: Beef tenderness markers in the three main French breeds: a proteomic analyses. Proceedings of the BIT’s 2nd World DNA and Genome Day, Dalian, Chine; 2011:185.
• [46]Pulford DJ, Fraga Vazquez S, Frost DF, Fraser-Smith E, Dobbie P, Rosenvold K: The intracellular distribution of small heat shock proteins in post-mortem beef is determined by ultimate pH. Meat Sci 2008, 79:623-630.
• [47]Kim NK, Lim D, Lee SH, Cho YM, Park EW, Lee CS, Shin BS, Kim TH, Yoon D: Heat shock protein B1 and its regulator genes are negatively correlated with intramuscular fat content in the Longissimus Thoracis muscle of Hanwoo (Korean cattle) steers. J Agr Food Chem 2011, 59:5657-5664.
• [48]Kampinga HH, Hageman J, Vos MJ, Kubota H, Tanguay RM, Bruford EA, Cheetham ME, Chen B, Hightower LE: Guidelines for the nomenclature of the human heat shock proteins. Cell Stress Chaperones 2009, 14:105-111.
• [49]Zhao C, Tian F, Yu Y, Luo J, Hu Q, Bequette BJ, Baldwin Vi RL, Liu G, Zan L, Scott Updike M, Song J: Muscle transcriptomic analyses in Angus cattle with divergent tenderness. Mol Biol Rep 2012, 39:4185-93.
• [50]Jeremiah LE, Dugan MER, Aalhus JL, Gibson LL: Assessment of the relationship between chemical components and palatability of major beef muscles and muscle groups. Meat Sci 2003, 65:1013-1019.
• [51]Nishimura T, Hattori A, Takahashi K: Structural changes in intramuscular connective tissue during the fattening of Japanese black cattle: effect of marbling on beef tenderization. J Anim Sci 1999, 77:93-104.
• [52]Lee SH, Joo ST, Ryu Y: C.Skeletal muscle fiber type and myofibrillar proteins in relation to meat quality. Meat Sci 2006, 86:166-170.
• [53]Maltin C, Balcerzak D, Tilley R, Delday M: Determinants of meat quality: Tenderness. Proc Nutr Soc 2003, 62:337-347.
• [54]De Jager N, Hudson NJ, Reverter A, Cafe LM, Greenwood PL, Wang YH, Pethick DW, Barnard R, Dalrymple BP: Effects of tenderness genotypes and of experimental site on the expression of fat and ribosomal module genes. Proceedings of the 9th World congress on Genetics Applied to Livestock Production, Leipzig, Germany; 2010.